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An algorithmic framework for generating optimal two-stratum experimental designs

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  • CUERVO, Daniel Palhazi
  • GOOS, Peter
  • SÖRENSEN, Kenneth

Abstract

Two-stratum experiments are widely used in case a complete randomization is not possible. In some experimental scenarios, there are constraints that limit the number of observations that can be made under homogeneous conditions. In other scenarios, there are factors whose levels are hard or expensive to change. In both of these scenarios, it is necessary to arrange the observations in different groups. Moreover, it is important that the analysis performed accounts for the variation in the response variable due to the differences between the groups. The most common strategy for the design of these kinds of experiments is to consider groups of equal size. The number of groups and the number of observations per group are usually defined by the constraints that limit the experimental scenario. We argue, however, that these constraints do not de ne the design itself, but should be considered only as upper bounds. The number of groups and the number of observations per group should be chosen not only to satisfy the experimental constraints, but also to maximize the quality of the experiment. In this paper, we propose an algorithmic framework to generate optimal designs for two-stratum experiments in which the number of groups and the number of observations per group are limited only by upper bounds. The results of an extensive set of computational simulations show that this additional exibility in the design generation process can significantly improve the quality of the experiments. Moreover, the results show that the grouping configuration of an optimal design depends on the characteristics of the two-stratum experiment, namely, the type of experiment, the model to be estimated and the optimality criterion considered. This is certainly a strong argument in favour of using algorithmic techniques that are able to identify not only the best factor-level con guration for each experimental run, but also the best grouping configuration.

Suggested Citation

  • CUERVO, Daniel Palhazi & GOOS, Peter & SÖRENSEN, Kenneth, 2016. "An algorithmic framework for generating optimal two-stratum experimental designs," Working Papers 2016003, University of Antwerp, Faculty of Business and Economics.
    • Handle: RePEc:ant:wpaper:2016003
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    References listed on IDEAS

    as
    1. Steven G. Gilmour & Peter Goos, 2009. "Analysis of data from non‐orthogonal multistratum designs in industrial experiments," Journal of the Royal Statistical Society Series C, Royal Statistical Society, vol. 58(4), pages 467-484, September.
    2. Trinca, Luzia A. & Gilmour, Steven G., 2000. "An algorithm for arranging response surface designs in small blocks," Computational Statistics & Data Analysis, Elsevier, vol. 33(1), pages 25-43, March.
    3. Bradley Jones & Peter Goos, 2009. "D-optimal design of split-split-plot experiments," Biometrika, Biometrika Trust, vol. 96(1), pages 67-82.
    4. Kessels, Roselinde & Goos, Peter & Vandebroek, Martina, 2008. "Optimal designs for conjoint experiments," Computational Statistics & Data Analysis, Elsevier, vol. 52(5), pages 2369-2387, January.
    5. Jianxin Wang & Ye Yuan & Shengli Zhao, 2015. "Fractional Factorial Split-plot Designs with Two- and Four-level Factors Containing Clear Effects," Communications in Statistics - Theory and Methods, Taylor & Francis Journals, vol. 44(4), pages 671-682, February.
    6. ARNOUTS, Heidi & GOOS, Peter, 2013. "Staggered-level designs for response surface modeling," Working Papers 2013027, University of Antwerp, Faculty of Business and Economics.
    7. L. A. Trinca & S. G. Gilmour, 1999. "Difference variance dispersion graphs for comparing response surface designs with applications in food technology," Journal of the Royal Statistical Society Series C, Royal Statistical Society, vol. 48(4), pages 441-455.
    8. Bradley Jones & Peter Goos, 2007. "A candidate‐set‐free algorithm for generating D‐optimal split‐plot designs," Journal of the Royal Statistical Society Series C, Royal Statistical Society, vol. 56(3), pages 347-364, May.
    9. Smucker, Byran J. & Castillo, Enrique del & Rosenberger, James L., 2012. "Model-robust designs for split-plot experiments," Computational Statistics & Data Analysis, Elsevier, vol. 56(12), pages 4111-4121.
    10. D. R. Bingham & E. D. Schoen & R. R. Sitter, 2004. "Designing fractional factorial split‐plot experiments with few whole‐plot factors," Journal of the Royal Statistical Society Series C, Royal Statistical Society, vol. 53(2), pages 325-339, April.
    11. Sambo, Francesco & Borrotti, Matteo & Mylona, Kalliopi, 2014. "A coordinate-exchange two-phase local search algorithm for the D- and I-optimal designs of split-plot experiments," Computational Statistics & Data Analysis, Elsevier, vol. 71(C), pages 1193-1207.
    12. Shengli Zhao & Xiangfei Chen, 2012. "Mixed-level fractional factorial split-plot designs containing clear effects," Metrika: International Journal for Theoretical and Applied Statistics, Springer, vol. 75(7), pages 953-962, October.
    13. Peter Goos, 2006. "Optimal versus orthogonal and equivalent‐estimation design of blocked and split‐plot experiments," Statistica Neerlandica, Netherlands Society for Statistics and Operations Research, vol. 60(3), pages 361-378, August.
    14. D. R. Bingham & E. D. Schoen & R. R. Sitter, 2005. "Corrigendum: Designing fractional factorial split‐plot experiments with few whole‐plot factors," Journal of the Royal Statistical Society Series C, Royal Statistical Society, vol. 54(5), pages 955-958, November.
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